KR19990027500A - Freezing method of gas boiler - Google Patents

Abstract

The present invention relates to a method of preventing the freezing of a gas boiler, and more particularly, to prevent the freezing generated by the stop of the gas boiler by performing the freezing function when the temperature sensor of the gas boiler fails in winter. The present invention relates to a method of preventing freezing of a gas boiler.

The freeze protection method of the gas boiler according to the present invention receives the signal of the temperature sensing unit 20, the room cone 12 for detecting the temperature of the heating water or outputs a signal to the room cone 12 and controls each element that is electrically operated. In the gas boiler comprising a microcomputer 14, a bi-directional pump 8 to switch the direction while circulating the heating water, and a heater 21 for heating the direct water, it is returned to the heat exchanger (4) of the gas boiler A determination step of determining whether the temperature sensing unit 20 for detecting the temperature of the heating water is a failure, and if the temperature sensing unit 20 is broken in the determination step, an error is displayed on the room cone 12 and the heater 21 And a freeze delay step of applying a current to the bidirectional pump (8).

Description

Freezing method of gas boiler

The present invention relates to a method of preventing the freezing of a gas boiler, and more particularly, to prevent the freezing generated by the stop of the gas boiler by performing the freezing function when the temperature sensor of the gas boiler fails in winter. The present invention relates to a method of preventing freezing of a gas boiler.

In general, a gas boiler has a function of using the heat of combustion of gas as heating water or using direct water (cold water) directly as hot water.

1 and 2 is a schematic configuration diagram showing an example of a conventional gas boiler.

As shown in the drawing, when the gas valve 1 is opened, gas is introduced into the burner 3 along the gas supply pipe 2, and the burner 3 mixes gas and air to combust it. The combustion gas includes a structure that is discharged through the flue 5 after heating the heat exchanger (4).

In the heat exchanger (4), the circulating heating water is heated to be transferred to the water tank (6) or the hot water heat exchanger (7) along the hose, and the heating water is heated for heating by the rotational direction of the bidirectional pump (8). It flows out through the water supply pipe 9 or flows directly into the hot water heat exchanger 7.

For example, when hot water is used, the direct water flows into the hot water heat exchanger 7 through the direct water supply pipe 10, and the hot water heat exchanger 7 heats the direct water with hot water and flows out into the hot water discharge pipe 11.

That is, when the user sets the room cone 12 to the hot water mode and opens the hot water valve (not shown), the flow switch 13 installed in the direct water supply pipe 10 operates to operate the bidirectional pump 8 in the direction of using hot water. do.

Then, the heating water of the heat exchanger (4) flows into the hot water heat exchanger (7) via the water tank (6) and the bidirectional pump (8) by driving the bidirectional pump (8), and the hot water heat exchanger (7). From the flow back to the heat exchanger (4).

Here, the heating water flows in isolation from the direct water, which receives the heat from the heating water, becomes hot water, and flows out into the hot water discharge pipe 11.

On the other hand, when the water in the water tank 6 is lowered due to evaporation or the like, the water is replenished. At this time, the microcomputer 14 operates the automatic refill water valve 15 to supply water directly to the water tank 6. Done.

The automatic supplement water valve 15 is installed on the supplementary water supply pipe 16 connected to the direct water supply pipe 10 while being installed at one outlet side of the hot water heat exchanger 7, and the supplementary water supply pipe 16 is It is connected to the water tank (6).

In the conventional gas boiler, a temperature sensing unit 20 is installed at the water outlet side and the water inlet side of the heat exchanger 4 and the direct water supply pipe 10, and an overheat prevention temperature sensor 20a and a heating supply water temperature sensor are provided at the water outlet side. 20b) is installed, the heating return temperature sensor 20c is installed on the inlet side, and the freeze protection temperature sensor 20d is installed on the direct water supply pipe 10.

The heater 21 is installed on the direct water supply pipe 10 together with the freeze protection temperature sensor 20d.

Such a gas boiler includes a freeze protection function expected in winter, and the freeze protection function is roughly classified into a freeze protection pump driving and a freeze protection combustion.

For example, in the freeze protection pump driving, when the heating supply water temperature sensor 20b of the temperature sensing unit 20 detects a temperature at which freezing is expected, that is, heating water below 4 ° C. and outputs the temperature to the microcomputer 14, 14 drives the bidirectional pump 8.

At this time, the bidirectional pump 8 repeatedly operates for a time set in a heating mode and a hot water mode.

When the heating supply water temperature sensor 20b of the temperature sensing unit 20 detects a temperature at which freezing cannot occur, that is, 7 ° C. or more, the microcomputer 14 receiving this signal stops the operation of the bidirectional pump 8. do.

Meanwhile, the freeze protection function stops the operation of the gas boiler when a failure of the temperature sensing unit 20 is detected.

By the way, if the failure of the temperature sensing unit 20 is detected as described above, the freeze protection method which stops the operation of the gas boiler simply stops the operation of the gas boiler without delaying the freezing of the pipe in winter, and thus the simple temperature sensing unit 20. ), There is a problem that does not delay or prevent the freezing of the gas boiler and pipes, resulting in a greater loss.

The present invention has been made to solve the above-mentioned problems of the prior art, it is possible to easily prevent the freeze caused by the stop of the gas boiler by performing the freeze protection function when the temperature sensor of the gas boiler in winter breaks. The purpose is to provide a freeze protection method for gas boilers.

The freezing prevention method of the gas boiler according to the present invention for achieving the above object is a temperature sensing unit for detecting the temperature of the heating water, receiving a signal of the room cone or outputs a signal to the room cone and controls each element that is electrically operated. In a gas boiler including a microcomputer, a bidirectional pump for changing its direction while circulating heating water, and a heater for heating direct water, the temperature sensing unit for detecting a temperature of the heating water returned to the heat exchanger of the gas boiler determines whether there is a failure. Determining step, if the temperature sensing unit in the determination step characterized in that it comprises a freeze delay step of displaying an error in the room cone and applying a current to the heater and the bidirectional pump.

1 is a configuration diagram showing an example of a gas boiler;

2 is a block diagram of FIG. 1;

3 is a flowchart showing a method of preventing freezing of a gas boiler according to the present invention.

Explanation of symbols for the main parts of the drawings

1: gas valve 2: gas supply pipe

3: burner 4: heat exchanger

5: year 6: water tank

7: hot water heat exchanger 8: bidirectional pump

9: heating water supply pipe 10: direct water supply pipe

11: hot water discharge pipe 12: room cone

13: flow switch 14: microcomputer

15: automatic refill water valve 16: replenishment water supply pipe

20: temperature detection unit 20a: overheat prevention temperature sensor

20b: Heating supply temperature sensor 20c: Heating return temperature sensor

20d: Freeze protection temperature sensor 21: Heater

BEST MODE Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a configuration diagram illustrating an example of a gas boiler, FIG. 2 is a block diagram of FIG. 1, and FIG. 3 is a flowchart illustrating a freezing prevention method of a gas boiler according to the present invention.

As shown in the drawing, when the gas valve 1 is opened, gas is introduced into the burner 3 along the gas supply pipe 2, and the burner 3 mixes gas and air to combust it. The combustion gas includes a structure that is discharged through the flue 5 after heating the heat exchanger (4).

In the heat exchanger (4), the circulating heating water is heated to be transferred to the water tank (6) or the hot water heat exchanger (7) along the hose, and the heating water is heated for heating by the rotational direction of the bidirectional pump (8). It flows out through the water supply pipe 9 or flows directly into the hot water heat exchanger 7.

For example, when hot water is used, the direct water flows into the hot water heat exchanger 7 through the direct water supply pipe 10, and the hot water heat exchanger 7 heats the direct water with hot water and flows out into the hot water discharge pipe 11.

That is, when the user sets the room cone 12 to the hot water mode and opens the hot water valve (not shown), the flow switch 13 installed in the direct water supply pipe 10 operates to operate the bidirectional pump 8 in the direction of using hot water. do.

Then, the heating water of the heat exchanger (4) flows into the hot water heat exchanger (7) via the water tank (6) and the bidirectional pump (8) by driving the bidirectional pump (8), and the hot water heat exchanger (7). From the flow back to the heat exchanger (4).

Here, the heating water flows in isolation from the direct water, which receives the heat from the heating water, becomes hot water, and flows out into the hot water discharge pipe 11.

The gas boiler is provided with a temperature sensing unit 20 on the water outlet side and the water inlet side of the heat exchanger 4 and the direct water supply pipe 10, on the water outlet side, an overheat prevention temperature sensor 20a and a heating supply water temperature sensor ( 20b) is installed, the heating return temperature sensor 20c is installed on the inlet side, and the freeze protection temperature sensor 20d is installed on the water supply pipe 10, and the freeze prevention temperature sensor (10) is provided on the water supply pipe 10. In addition to 20d), the heater 21 is provided.

In the present invention, since the overheat prevention temperature sensor 20a and the heating return temperature sensor 20c of the temperature detection unit 20 may be used, the number of the temperature detection unit 20 can be reduced.

Therefore, the freeze protection method of the gas boiler according to the present invention determines whether the temperature sensing unit 20 that detects the temperature of the heating water returned to the heat exchanger 4 of the gas boiler, that is, the heating return temperature sensor 20c, is faulty. In the determining step and the determining step, if the temperature detecting unit 20, that is, the heating return temperature sensor 20c, displays an error in the room cone 12 and applies a current to the heater 21 and the bidirectional pump 8. It includes a freeze delay step.

That is, it includes a freeze delay step in the case of a conventional freeze pump operation and freeze combustion and the failure of the temperature sensing unit 20 mentioned in the present invention.

Here, the bidirectional pump 8 of the freeze delay step preferably operates the heating mode and the hot water mode repeatedly for a predetermined time.

Then, even if the temperature sensing unit 20 is broken by at least the circulation of the heating water and the direct water heating, the gas boiler, the heating pipe and the hot water pipe are protected.

As described above, the method of preventing the freezing of the gas boiler according to the present invention prevents the freezing of the minimum gas boiler and the pipe even though a failure of the temperature sensing unit, in particular, the heating return temperature sensor, prevents the gas boiler and the pipe easily. The advantage is protection.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments, and that various modifications and changes can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the claims of the present invention.

Claims (2)

The temperature sensing unit 20 for detecting the temperature of the heating water, the signal received from the room cone 12 or outputs a signal to the room cone 12, the microcomputer 14 for controlling each element that is electrically operated, while circulating the heating water In the gas boiler comprising a two-way pump (8) for switching the direction, and a heater (21) for heating the direct water, Determination step of determining whether the temperature detection unit 20 for detecting the temperature of the heating water returned to the heat exchanger (4) of the gas boiler is broken, and In the determination step, if the temperature detection unit 20 is broken, an error is displayed on the room cone 12 and a freeze delay step of applying a current to the heater 21 and the bidirectional pump 8 is characterized in that it is made. Freezing method of gas boiler. The method of claim 1, wherein the bidirectional pump of the freeze delay step repeatedly operates the heating mode and the hot water mode for a predetermined time.